Wearable electronics,as essential components of the Internet of Things(IoT),have attracted widespread attention,and the trend is to configure attractive wearable smart microsystems by integrating sensing,powering,and ...Wearable electronics,as essential components of the Internet of Things(IoT),have attracted widespread attention,and the trend is to configure attractive wearable smart microsystems by integrating sensing,powering,and other,functions.Herein,we developed an elastic hybrid triboelectric-electromagnetic microenergy harvester(named EHTE)to realize hybrid sensing and microenergy simultaneously.This EHTE is a highly integrated triboelectric nanogenerator(TENG)and electromagnetic nanogenerator(EMG).Based on the triboelectric-electromagnetic hybrid mechanism,an enhanced electrical output of the EHTE was achieved successfully,which demonstrates the feasibility of the EHTE for microelectronics powering.Moreover,with the merits of the EMG,the developed hybrid microenergy harvester integrated both active frequency sensing and passive inductive sensing capabilities.Specifically,the almost linear correlation of the electromagnetic outputs to the frequencies of the external stimulus endowed the proposed EHTE with an outstanding active frequency sensing ability.in addition,due to the unique structural configuration of the EMG(i.e,a conductive permanent magnet(PM),hybrid deformation layer,and flexible printed circuit board(FPCB)coil),an opportunity was provided for the developed EHTE to serve as a passive inductive sensor based on the eddy current effect(ie.,a form of electromagnetic induction).Therefore,the developed EHTE successfully achieved the integration of hybrid sensing(i.e,active frequency sensing and passive inductive sensing)and microenergy(ie,the combination of electromagnetic effect and triboelectric effect)within a single device,which demonstrates the potential of this newly developed EHTE for wearable electronic applications,especially in applications of compact active microsystems.展开更多
基金supported by theNational Natural Science Foundation of China(No.62074029,No.61905035,No.61971108,No.62004029,No.51905554)the Key R&D Program of Sichuan Province(No.2022JDTD0020,No.2022YFG0163,No.2020ZHCG0038)+1 种基金the Sichuan Science and Technology Program(No.2020YJ0015)the Fundamental Research Funds for the Central Universities(No.ZYGX2019Z002).
文摘Wearable electronics,as essential components of the Internet of Things(IoT),have attracted widespread attention,and the trend is to configure attractive wearable smart microsystems by integrating sensing,powering,and other,functions.Herein,we developed an elastic hybrid triboelectric-electromagnetic microenergy harvester(named EHTE)to realize hybrid sensing and microenergy simultaneously.This EHTE is a highly integrated triboelectric nanogenerator(TENG)and electromagnetic nanogenerator(EMG).Based on the triboelectric-electromagnetic hybrid mechanism,an enhanced electrical output of the EHTE was achieved successfully,which demonstrates the feasibility of the EHTE for microelectronics powering.Moreover,with the merits of the EMG,the developed hybrid microenergy harvester integrated both active frequency sensing and passive inductive sensing capabilities.Specifically,the almost linear correlation of the electromagnetic outputs to the frequencies of the external stimulus endowed the proposed EHTE with an outstanding active frequency sensing ability.in addition,due to the unique structural configuration of the EMG(i.e,a conductive permanent magnet(PM),hybrid deformation layer,and flexible printed circuit board(FPCB)coil),an opportunity was provided for the developed EHTE to serve as a passive inductive sensor based on the eddy current effect(ie.,a form of electromagnetic induction).Therefore,the developed EHTE successfully achieved the integration of hybrid sensing(i.e,active frequency sensing and passive inductive sensing)and microenergy(ie,the combination of electromagnetic effect and triboelectric effect)within a single device,which demonstrates the potential of this newly developed EHTE for wearable electronic applications,especially in applications of compact active microsystems.